Receiver device, communications device, wireless LAN device, power control method for a receiver device, power control program for a receiver device, and storage medium

ABSTRACT

A receiver device in accordance with the present invention (for example, wireless LAN device) includes: a radio frequency signal processor section converting an incoming radio frequency signal to a lower frequency; an RSSI circuit (reception strength sensor section) sensing the signal strength of the radio frequency signal; an intermediate frequency signal processor section converting a signal from the radio frequency signal processor section to an even lower frequency; a digital demodulator section (demodulator section) demodulating a signal from the intermediate frequency signal processor section; and a power control circuit controlling power supply to circuits in the intermediate frequency signal processor section which makes up part of the analog section (AGC circuit, IF mixer circuit, LPF circuit, and amplifier circuit) according to a result of sensing by the RSSI circuit. The structure provides a power saving receiver device.

This Nonprovisional application claims priority under 35 U.S.C. § 119(a)on Patent Application No. 2004-198605 filed in Japan on Jul. 5, 2004 andProvisional Patent Application No. 60/587,514 filed in the U.S., theentire contents of which are hereby incorporated by reference.

FIELD OF THE INVENTION

The present invention relates to power savings in receiver devices for,among others, double heterodyne or direct conversion wireless LANterminals.

BACKGROUND OF THE INVENTION

FIG. 6 is a block diagram showing a conventional power saving structurefor the wireless LAN device disclosed in Japanese unexamined patentapplication 8-307428 (Tokukaihei 8-307428/1996; published on 22 Nov.1996). A receiver section 202 in the conventional wireless LAN device201 includes: a radio section 225 which makes up the analog section; anda reception strength determine section 226, a power/clock controlsection 227, an A/D converter section 228, a despreader/demodulatorsection 229, an amplitude sensor section 230, a synchronizationintegrator section 231, a synchronization detector section 232, and aninformation demodulator section 233 which make up a digital section.

The radio section 225 operates in the analog domain. The section 225produces an intermediate frequency from an RF (radio frequency) signalreceived by an antenna 224 with an internal amplifier and filter, toobtain a necessary reception strength. The reception strength determinesection 226 amplifies, rectifies, and smoothes the intermediatefrequency signal and compares the resultant signal strength to apredetermined value with an internal comparator to determine whether tostart reception. The power/clock control section 227 controls power andclock supply to each block. The A/D converter section 228 converts theoutput of the radio section 225 from analog to digital. Thedespreader/demodulator section 229 demodulates a spread signal bydespreading. The amplitude sensor section 230 produces a valueindicating the amplitude of the output of the despreader/demodulatorsection 229. The synchronization integrator section 231 integrates theoutput of the amplitude sensor section 230 for each symbol. Thesynchronization detector section 232 produces a synchronization signalfrom the output of the synchronization integrator section 231. Theinformation demodulator section 233 demodulates for information based onthe output of the amplitude sensor section 230 and the synchronizationsignal output of the synchronization detector section 232.

Now, the receiver section 202 in the wireless LAN device 201 will bedescribed in terms of its operation.

In reception standby periods, only the radio section 225 (analogsection), the reception strength determine section 226, and thepower/clock control section 227 are in operation. The power/clockcontrol section 227, in the reception standby period, is suspendingoperation clock supply to the A/D converter section 228, thedespreader/demodulator section 229, the amplitude sensor section 230,the synchronization integrator section 231, the synchronization detectorsection 232, and the information demodulator section 233 which thereforeare not operating.

In these circumstances, the reception strength determine section 226amplifies the intermediate frequency signal from the radio section 225and compares the strength of the intermediate frequency signal to avalue specified by the terminal device with an internal comparator. Ifthe strength of the intermediate frequency signal is greater, receptionis started.

Following the start of reception, the power/clock control section 227supplies an operation clock to the A/D converter section 228, thedespreader/demodulator section 229, the amplitude sensor section 230,the synchronization integrator section 231, the synchronization detectorsection 232, and the information demodulator section 233 to place themin operation.

After a termination of reception, only the radio section 225 (analogsection), the reception strength determine section 226, and thepower/clock control section 227 are again in operation.

The structure lowers power consumption in the wireless LAN device whichstands by for an extended period of time for reception.

However, in this conventional structure, in reception standby periodswhen the digital section (A/D converter section 228,despreader/demodulator section 229, amplitude sensor section 230,synchronization integrator section 231, synchronization detector section232, and information demodulator section 233) is not operating, theradio section 225 (analog section) is in operation. The radio section225 includes various analog circuits which, when combined, consume quitea lot of operating power. This waste of power cannot be ignored,especially, when the wireless LAN device is mounted to a mobileterminal.

SUMMARY OF THE INVENTION

The present invention, in view of these problems, has an objective toprovide a receiver device (for example, wireless LAN device) capable ofpower savings.

A receiver device in accordance with the present invention, to addressthese issues, includes:

a first signal processor section converting an incoming radio frequencysignal to a lower frequency;

a reception strength sensor section sensing a signal strength of theradio frequency signal;

a second signal processor section carrying out a process on a signalfrom the first signal processor section to improve demodulationprecision;

a demodulator section demodulating a signal from the second signalprocessor section; and

a power control section controlling power supply to circuits in thesecond signal processor section according to a result of sensing by thereception strength sensor section.

According to the arrangement, the first signal processor sectionconverts an incoming radio frequency signal to a lower frequency (forexample, baseband signal). Meanwhile, the reception strength sensorsection senses the signal strength of the incoming radio frequencysignal.

The output signal from the first signal processor section is processed(for example, auto gain control and amplification) in the second signalprocessor section for better demodulation precision. The output signalfrom the second signal processor section is demodulated in thedemodulator section to reproduce transmitted information.

The power control section controls power supply to the circuits in thesecond signal processor section according to the result of the sensingby the reception strength sensor section. For example, power supply tothe second signal processor section is suspended until the result of thesensing by the reception strength sensor section meets a predeterminedcondition. As a result, unlike conventional art where the entire analogsection is always powered and kept in operation (see FIG. 6), powerwaste in the second signal processor section is greatly reduced whilethe analog section is waiting for a signal to be received (demodulatablesignal) (during reception standby). The arrangement thus achieves powersavings in the receiver device.

Another receiver device in accordance with the present invention, toaddress the issues, includes:

a radio frequency signal processor section converting an incoming radiofrequency signal to a lower frequency;

a reception strength sensor section sensing a signal strength of theradio frequency signal;

an intermediate frequency signal processor section converting a signalfrom the radio frequency signal processor section to an even lowerfrequency;

a demodulator section demodulating a signal from the intermediatefrequency signal processor section; and

a power control section controlling power supply to circuits in theintermediate frequency signal processor section according to a result ofsensing by the reception strength sensor section.

According to the arrangement, the radio frequency signal processorsection converts an incoming radio frequency signal to a lower frequency(for example, intermediate frequency signal). The signal output of theradio frequency signal processor section is converted in theintermediate frequency signal processor section to an even lowerfrequency (for example, baseband signal). Meanwhile, the receptionstrength sensor section senses the signal strength of the incoming radiofrequency signal. The output signal from the intermediate frequencysignal processor section is fed to the demodulator section fordemodulation to reproduce transmitted information.

The power control section controls power supply to the circuits in theintermediate frequency signal processor section according to the resultof the sensing by the reception strength sensor section. For example,power supply to the intermediate frequency signal processor section issuspended until the result of the sensing by the reception strengthsensor section meets a predetermined condition. As a result, unlikeconventional art where the entire analog section is always powered andkept in operation (see FIG. 6), power waste in the intermediatefrequency signal processor section is greatly reduced while the analogsection is waiting for a signal to be received (demodulatable signal)(during reception standby). The arrangement thus achieves power savingsin the receiver device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing an arrangement of a wireless LANterminal (receiver section) in accordance with embodiment 1 of thepresent invention.

FIG. 2 is a flow chart illustrating the control the operation state ofthe wireless LAN terminal in FIG. 1.

FIG. 3 is a block diagram showing an arrangement of a wireless LANterminal (receiver section) in accordance with embodiment 2 of thepresent invention.

FIG. 4 is a flow chart illustrating the control the operation state ofthe wireless LAN terminal in FIG. 3.

FIG. 5 is a block diagram showing an arrangement of a signal detectorsection in accordance with embodiment 2 of the present invention.

FIG. 6 is a block diagram showing an arrangement of a conventional(power saving) wireless LAN device.

DESCRIPTION OF THE EMBODIMENTS Embodiment 1

Referring to FIGS. 3, 4, the following will describe another embodimentin accordance with the wireless LAN terminal (receiver device, wirelessLAN device) of the present invention.

As shown in the figures, a receiver section 102 in a wireless LANterminal 101 in accordance with the present embodiment has a directconversion structure composed chiefly of a radio frequency signalprocessor section (first signal processor section) 104, a signaldetector section 106, a gain regulator section (second signal processorsection) 105, a digital demodulator section (demodulator section) 107, again control section 108, and an operation state control section 109.

The radio frequency signal processor section 104, the gain regulatorsection 105, and a part of the signal detector section 106 (RSSI circuit131) make up an analog section 110. Another part of the signal detectorsection 106 (ADC 132, reception start determine section 133), thedigital demodulator section 107, the gain control section 108, and theoperation state control section 109 make up a digital section 120.

The radio frequency signal processor section 104 includes an antenna111, a low noise amplifier (LNA) 112, a radio frequency oscillator(RFOSC) 113, two radio frequency mixers (RF mixers) 114 a, 114 b, andtwo low pass filters (LPFs) 115 a, 115 b. The antenna 111 receives aradio frequency signal (RF signal) from a LAN (local area network) 103between which and the wireless LAN terminal 101 is established awireless link. The low noise amplifier 112 amplifies the radio signal111 received by the antenna 111 at a low NF (noise figure) beforefeeding the signal to both the radio frequency mixers (RF mixers) 114 a,114 b. The radio frequency oscillator 113 oscillates to generate asignal which is used in down converting the radio frequency signal to abaseband signal. The radio frequency mixer 114 a mixes one of the signaloutputs of the low noise amplifier 112 with an oscillating signal fromthe radio frequency oscillator 113 to produce a baseband signal(in-phase component) output. The radio frequency mixer 114 b mixes theother signal output of the low noise amplifier 112 with the oscillatingsignal from the radio frequency oscillator 113 after a π/2phase-shifting of the oscillating signal, to produce a baseband signal(quadrature component) output. The low pass filter 115 a removesunnecessary components from the baseband signal (in-phase component)output of the radio frequency mixer 114 a to generate a signal at atarget frequency. The low pass filter 115 b removes unnecessarycomponents from the baseband signal (quadrature component) output of theradio frequency mixer 114 b to generate a signal at a target frequency.

The gain regulator section 105 include an AGC circuit (auto gain controlcircuit, gain regulator circuit) 122 and two amplifier circuits (AMPcircuits) 126 a, 126 b. The amplifier circuit 126 a amplifies the outputof the low pass filter circuit 115 a which is the baseband signal(in-phase component) minus unnecessary components. The amplifier circuit126 b amplifies the output of the low pass filter circuit 115 b which isthe baseband signal (quadrature component) minus unnecessary components.

The signal detector section 106 includes the RSSI (receive signalstrength indicator) circuit (reception strength sensor section) 131which makes up part of the analog section 110; and the A/D converter(ADC) 132 and the reception start determine section 133 which make uppart of the digital section 120. The RSSI circuit 131 generates an RSSIsignal from the baseband signal output of the lowpass filter 115 foroutput to the A/D converter 132. The A/D converter 132 then digitizesthe RSSI signal detected in the RSSI circuit 131 for output to thereception start determine section 133. The structure of the receptionstart determine section 133 and the scheme to determine whether to startreception are similar to embodiment 1 (see FIG. 5). In short, when anincrease in the RSSI value from the RSSI circuit 131 (the result ofsensing by the reception strength sensor section) is greater than athreshold increase value (when the increase meets a predeterminedcondition), a signal is determined to have been detected, and areception start signal is sent to the operation state control section109. The reception start determine section 133 supplies the RSSI valueas indicating the reception strength to the gain control section 108. Bymaking a decision to start reception based on a sample value increaseexceeding a threshold value in this manner, the targeted incoming signalis not missed in the input which may include both the target signal andinterference signals. A reception start is accurately determined.

The reference does not necessarily provided by the delay circuit, butmay be provided by a sample and hold circuit which samples the RSSIsignal and holds the value at certain times. The reception startdetermine section 133 may include a simple arrangement to determinewhether the reception strength output of the A/D converter 132 (theresult of sensing by the reception strength sensor section) exceeds athreshold value (predetermined level) and if so, supply a receptionstart signal to the operation state control section 109.

The digital demodulator section 107 includes two ADCs (A/D converters)141 a, 141 b and a BB (baseband) demodulator circuit 142. The A/Dconverter 141 a converts the baseband signal from the amplifier circuit126 a from analog to digital. Similarly, the A/D converter 141 bconverts the baseband signal from the amplifier circuit 126 b fromanalog to digital. The baseband demodulator circuit 142 demodulates thedigital signal outputs of the A/D converters 141 a, 141 b to reproduceoriginal data (transmitted information) for output to an upper layer.Having completed the signal (packet data) demodulation, the basebanddemodulator circuit 142 sends a packet terminate signal to the operationstate control section 109.

The gain control section 108 includes an AGC control circuit 150 and aDAC (D/A converter) 160. The AGC control circuit 150 controls the AGCcircuit 122 according to the reception strength output of the receptionstart determine section 133. Having completed the control of the AGCcircuit 122, the AGC control circuit 150 sends an AGC control completionsignal to the operation state control section 109.

The operation state control section 109 includes an operation clockcontrol circuit (digital operation control section) 151 and a powercontrol circuit (power control section) 152. In response to a receptionstart signal from the reception start determine section 133, theoperation clock control circuit 151 supplies an operation clock to thedigital demodulator section 107 and the gain control section 108 so thatthe sections 107, 108 can operate. In response to the reception startsignal from the reception start determine section 133, the power controlcircuit 152 supplies power to the gain regulator section 105 so that thecircuit can operate.

In response to an AGC control completion signal from the AGC controlcircuit 150, the operation state control section 109 controls the signaldetector section 106 (RSSI circuit 131, ADC 132, and reception startdetermine section 133). In other words, the power control circuit 152suspends power supply to the RSSI circuit 131 in response to an AGCcontrol completion signal so that the circuit 131 stops operating. Inresponse to the AGC control completion signal, the operation clockcontrol circuit 151 suspends operation clock supply to the ADC 132 andthe reception start determine section 133 so that they stop operating.

In response to the packet terminate signal from the baseband demodulatorcircuit 142, the operation state control section 109 controls theoperation of the gain regulator section 105, the signal detector section106, the digital demodulator section 107, and the gain control section108. In other words, the operation clock control circuit 151, inresponse to the packet terminate signal, suspends operation clock supplyto the digital demodulator section 107 and the gain control section 108so that the sections 107, 108 stop operating, and starts operation clocksupply to the ADC 132 and the reception start determine section 133 sothat they start operating. The power control circuit 152, in response tothe packet terminate signal, stops power supply to the gain regulatorsection 105 so that the section 105 stops operating, and starts powersupply to the RSSI circuit 131 so that the circuit 131 can operate.

Next will be described steps of controlling the operation state of eachmember in the wireless LAN terminal 101 in reference to the FIG. 4 flowchart.

First, in the wireless LAN terminal 101 in accordance with the presentembodiment, in reception standby periods when no data (signal) is beingreceived, only the radio frequency signal processor section 104, thesignal detector section 106, and the operation state control section 109(operation clock control circuit 151 and power control circuit 152) arein operation; the gain regulator section 105 (analog section), the gaincontrol section 8, and the digital demodulator section 7 (digitalsection 20) are not in operation (S15).

In other words, in the reception standby period, the power controlcircuit 152 stops power supply to the gain regulator section 105. Also,the operation clock control circuit 151 stops operation clock supply tothe digital demodulator section 107 and the gain control section 108.This suspension of operation of the gain regulator section 105 in theanalog section, the digital demodulator section 7, and the gain controlsection 8 (digital section) in the reception standby period contributesto power savings. This is especially true with the wireless LAN terminalwhich stands by for an extended period of time for reception.

Note that the wireless LAN terminal 101 is able to recognize a data(packet) transmission to itself throughout the reception standby period,because the radio frequency signal processor section 104 and the signaldetector section 106 are still in operation.

If the reception start determine section 133 determines that the radiofrequency signal received by the radio frequency signal processorsection 104 (antenna 111) has a reception strength not less than apredetermined threshold value (S16), the wireless LAN terminal 101switches from a reception standby state to a receive state (S17). Thesignal processing flow (S15 to S17) is explained in detail in thefollowing.

A signal (radio frequency signal), received by the antenna 111, isamplified by the low noise amplifier 112 at a low NF and fed to both theradio frequency mixer 114 a and the radio frequency mixer 114 b. In theradio frequency mixer (RF mixer) 114 a, one of the signal outputs of thelow noise amplifier 112 is mixed with an oscillating signal from theradio frequency oscillator (RFOSC) 113. The mixing down converts asignal from the low noise amplifier 112 to a baseband signal (in-phasecomponent). The output signal from the radio frequency mixer 114 a isfed to the low pass filter 115 a where unnecessary components areremoved from the signal from the radio frequency mixer 114 a. The othersignal output of the low noise amplifier 112 is mixed in the radiofrequency mixer (RF mixer) 114 b with the oscillating signal from theradio frequency oscillator (RFOSC) 113 after a π/2 phase-shifting of theoscillating signal. The mixing down converts the signal from the lownoise amplifier 112 to a baseband signal (quadrature component). Theoutput signal from the radio frequency mixer 114 b is fed to the lowpass filter 115 b where unnecessary components are removed from thesignal from the radio frequency mixer 114 b.

The output signal from the low pass filter 115 is fed to the receptionstrength sensor section (RSSI) 131 where the RSSI value (receptionstrength) of the incoming signal is sensed. The RSSI value, as sensed bythe RSSI circuit 131, is digitized in the ADC 132 and supplied to thereception start determine section 133. If the RSSI value increases inexcess of a threshold increase value (over an early part of the RSSIvalue), the reception start determine section 133 determines that it hasdetected a signal (Yes in S16) and supplies a reception start signal tothe operation state control section 109. Reception is hence started(S17).

In response to the reception start signal from the reception startdetermine section 133, in the operation state control section 109, thepower control circuit 152 starts power supply to the gain regulatorsection 105, and the operation clock control circuit 151 startsoperation clock supply to the digital demodulator section 107 and thegain control section 108.

The actions turn on (activate) the gain regulator section 105, thedigital demodulator section 107, and the gain control section 108 whichhave been off (out of operation) (see S18). The radio frequency signalprocessor section 104 and the signal detector section 106 which havebeen energized (on) remain energized (on) (see S18).

As the gain control section 108 is activated, the reception startdetermine section 133 passes the RSSI value (reception strength) to theAGC control circuit 150. The AGC control circuit 150 controls the AGCcircuit 122 through DAC 160 on the basis of the reception strength. Whenthe AGC circuit 122 completes the control (Yes in S19), the AGC controlcircuit 150 transmits an AGC control completion signal to the operationstate control section 109.

This causes a switching to reception period power saving mode (Yes inS20). Specifically, having received the AGC control completion signal,the operation clock control circuit 151 stops operation clock supply tothe ADC 132 and the reception start determine section 133. The powercontrol circuit 152 stops power supply to the RSSI circuit 131. Thus,the signal detector section 106 stops operating, whereas the radiofrequency signal processor section 104, the gain regulator section 105,the digital demodulator section 107, and the gain control section 108remain in operation (S21). This action of suspending the operation ofthe signal detector section 106 (especially, suspending the power supplyto the RSSI circuit 131) during signal reception (from the start ofreception to the termination of the reception) contributes to furtherpower savings.

it is preferred if the reception period power saving mode is the defaultmode. The mode may not be selected; in which case, the signal detectorsection 106, the radio frequency signal processor section 104, the gainregulator section 105, the digital demodulator section 107, and the gaincontrol section 108 are all on (in operation) and remain in operation(S22).

Following S21 or S22, packet data is demodulated (S23). The signalprocessing in S23 is now detailed in the following.

When the AGC circuit 122 completes the control of the AGC controlcircuit 150 in S19, the output signal from one of low pass filters (115a) is suitably gain-regulated in the AGC circuit 122 and fed to theamplifier circuit 126 a for amplification. The output signal from theamplifier circuit 126 a is fed to the ADC 141 a in the digitaldemodulator section 107. The output signal from the other low passfilter (115 b) is suitably gain-regulated in the AGC circuit 122 and fedto the amplifier circuit 126 b for amplification. The output signal fromthe amplifier circuit 126 b is fed to the ADC 141 b in the digitaldemodulator section 107.

The baseband demodulator circuit (BB demodulator circuit) 142 in thedigital demodulator section 107 demodulates the incoming signal (packetdata) to the wireless LAN terminal 101 according to the signals from theA/D converter 141 a and the A/D converter 141 b. The demodulated data ispassed to an upper layer.

Having completed the signal demodulation (S24), the baseband demodulatorcircuit 142 sends a packet demodulation terminate signal to theoperation state control section 109. Thus, the wireless LAN terminal 101switches back to reception standby state (S25).

Specifically, having received a packet demodulation terminate signalfrom the baseband demodulator circuit 142, the power control circuit 152in the operation state control section 109 stops power supply to thegain regulator section 105, and starts power supply to the RSSI circuit131 in the signal detector section 106. The operation clock controlcircuit 151 stops operation clock supply to the digital demodulatorsection 107 and the gain control section 108, and starts power supply tothe ADC 132 and the reception start determine section 133 in the signaldetector section 106.

Embodiment 2

The following will describe an embodiment of the wireless LAN terminal(receiver device, communications device, wireless LAN device) of thepresent invention with reference to FIGS. 1, 2.

Referring first to FIG. 1, a receiver section 2 in a wireless LANterminal 1 in accordance with the present embodiment has a doubleheterodyne structure composed chiefly of a radio frequency signalprocessor section 4, a signal detector section 6, an intermediatefrequency signal processor section 5, a digital demodulator section(demodulator section) 7, a gain control section 8, and an operationstate control section 9.

The radio frequency signal processor section 4, the intermediatefrequency signal processor section 5, and a part of the signal detectorsection 6 (RSSI circuit 31) make up an analog section 10. Another partof the signal detector section 6 (ADC 32, reception start determinesection 33), the digital demodulator section 7, the gain control section8, and the operation state control section 9 make up a digital section20.

The radio frequency signal processor section 4 includes an antenna 11, alow noise amplifier (LNA) 12, a radio frequency oscillator (RFOSC) 13, aradio frequency mixer (RF mixer) 14, and a bandpass filter (BPF) 15. Theantenna 11 receives a radio frequency signal from a LAN (local areanetwork) 3 between which and the wireless LAN terminal 1 is establisheda wireless link. The low noise amplifier 12 amplifies the radio signal11 received by the antenna 11 at a low NF (noise figure). The radiofrequency oscillator 13 oscillates to generate a signal which is used indown converting the radio frequency signal to a lower frequency(intermediate frequency signal). The radio frequency mixer 14 mixes theradio frequency signal output of the low noise amplifier 12 with theoscillating signal output of the radio frequency oscillator 13 todeliver an intermediate frequency signal at a lower frequency than theradio frequency signal as an output. The bandpass filter 15 removesunnecessary components from the intermediate frequency signal output ofthe radio frequency mixer 14 to generate a signal at a target frequency.

The intermediate frequency signal processor section 5 includes an IFOSC(intermediate frequency oscillator, or abbreviated as “IF oscillator”)21, an AGC (auto gain control) circuit (gain regulator circuit) 22, twoIF (intermediate frequency) mixer circuits (simply “mixers”) 23 a, 23 b,two LPF (low pass filter) circuits 25 a, 25 b, and two AMP (amplifier)circuits 26 a, 26 b. The intermediate frequency oscillator 21 oscillatesto generate a signal which is used in down converting the intermediatefrequency signal to an even lower frequency (baseband signal). Theintermediate frequency mixer circuit 23 a mixes the intermediatefrequency signal output of the AGC circuit 22 with the oscillatingsignal output of the intermediate frequency oscillator 21 to deliver abaseband signal (in-phase component) as an output. The intermediatefrequency mixer circuit 23 b mixes the intermediate frequency signaloutput of the AGC circuit 22 with the oscillating signal output of theintermediate frequency oscillator 21 after a π/2 phase-shifting of theoscillating signal, to deliver a baseband signal (quadrature component)as an output. The low pass filter circuit 25 a removes unnecessarycomponents from the baseband signal (in-phase component) output of theintermediate frequency mixer circuit 23 a to generate a signal at atarget frequency. Similarly, the low pass filter circuit 25 b removesunnecessary components from the baseband signal (quadrature component)output of the intermediate frequency mixer circuit 23 b. The amplifiercircuit 26 a amplifies the output of the low pass filter circuit 25 awhich is the baseband signal (in-phase component) minus unnecessarycomponents. The amplifier circuit 26 b amplifies the output of the lowpass filter circuit 25 b which is the baseband signal (quadraturecomponent) minus unnecessary components.

The signal detector section 6 includes the RSSI (receive signal strengthindicator) circuit (reception strength sensor section) 31 which makes uppart of the analog section 10; and the ADC (A/D converter) 32 and thereception start determine section 33 which make up part of the digitalsection 20. The RSSI circuit 31 generates an RSSI signal from theintermediate frequency signal output of the bandpass filter 15 foroutput to the A/D converter 32. The A/D converter 32 then digitizes theRSSI signal detected in the RSSI circuit 31 for output to the receptionstart determine section 33.

The reception start determine section 33 determines whether to startreception as follows. Referring to FIG. 5 which is a block diagramshowing an arrangement of the reception start determine section 33, thereception start determine section 33 includes a delay circuit 81, asubtracter circuit 82, and a comparator circuit 83. In the arrangement,first, the delay circuit 81 delays sample values of an early part of thenow digitized RSSI signal. The delayed values will be used as areference in identify increases in the RSSI. The subtracter circuit 82subtracts this reference from succeeding sample values of the RSSIsignal to identify the RSSI value increase (the result of sensing by thereception strength sensor section). The comparator circuit 83 thencompares the RSSI value increase to a preset threshold increase value.If the RSSI value increase is greater than the threshold increase value(if the increase meets a predetermined condition), the circuit 83determines that a signal has been detected and transmits a receptionstart signal to the operation state control section 9. Also, thereception start determine section 33 supplies the RSSI value asindicating the reception strength to an AGC control circuit 50 in thegain control section 8. By making a decision to start reception based ona sample value increase exceeding a threshold value in this manner, thetargeted incoming signal is not missed in the input which may includeboth the target signal and interference signals. A reception start isaccurately determined.

The reference does not necessarily provided by the delay circuit 81, butmay be provided by a sample and hold circuit which samples the RSSIsignal and holds the value at certain times. The reception startdetermine section 33 may include a simple arrangement to determinewhether the reception strength output of the A/D converter 32 exceeds athreshold value (predetermined level) and if so, supply a receptionstart signal to the operation state control section 9.

The digital demodulator section 7 includes two ADCs (A/D converters) 41a, 41 b and a BB (baseband) demodulator circuit 42. The A/D converter 41a converts the baseband signal from the amplifier circuit 26 a fromanalog to digital. Similarly, the A/D converter 41 b converts a basebandsignal from the amplifier circuit 26 b from analog to digital. Thebaseband demodulator circuit 42 demodulates the digital signal outputsof the A/D converters 41 a, 41 b to reproduce original data (transmittedinformation) for output to an upper layer. Having completed the signal(packet data) demodulation, the baseband demodulator circuit 42 sends apacket terminate signal to the operation state control section 9.

The gain control section 8 includes an AGC control circuit 50 and a DAC(D/A converter) 60. The AGC control circuit 50 controls the AGC circuit22 according to the reception strength output of the reception startdetermine section 33. Having completed the control of the AGC circuit22, the AGC control circuit 50 sends an AGC control completion signal tothe operation state control section 9.

The operation state control section 9 includes an operation clockcontrol circuit (digital operation control section) 51 and a powercontrol circuit (power control section) 52. In response to a receptionstart signal from the reception start determine section 33, theoperation clock control circuit 51 supplies an operation clock to thedigital demodulator section 7 and the gain control section 8 so that thesections 7, 8 can operate. In response to a reception start signal fromthe reception start determine section 33, the power control circuit 52supplies power to the AGC circuit 22, the IF mixer circuits 23 a, 23 b,the LPF circuits 25 a, 25 b, and the amplifier circuits 26 a, 26 b, allin the intermediate frequency signal processor section 5, so that thecircuits can operate.

A reception status monitor section 66 which monitors the data receptionstate (reception interval) of the radio frequency signal processorsection 4 is provided in an upper layer relative to the physical layer.The circuit 52 controls power supply to (start/stop the operation of)the intermediate frequency oscillator (IFOSC) 21 according to an OSCcontrol signal from the reception status monitor section 66.

In response to an AGC control completion signal from the AGC controlcircuit 50, the operation state control section 9 controls the signaldetector section 6 (RSSI circuit 31, ADC 32, and reception startdetermine section 33). In other words, the power control circuit 52suspends power supply to the RSSI circuit 31 in response to an AGCcontrol completion signal so that the circuit 31 stops operating. Inresponse to the AGC control completion signal, the operation clockcontrol circuit 51 suspends operation clock supply to the ADC 32 and thereception start determine section 33 so that they stop operating.

In response to the packet terminate signal from the baseband demodulatorcircuit 42, the operation state control section 9 controls the operationof all the circuits in the intermediate frequency signal processorsection 5, as well as the operation of the signal detector section 6,the digital demodulator section 7, and the gain control section 8. Inother words, the operation clock control circuit 51, in response to thepacket terminate signal, suspends operation clock supply to the digitaldemodulator section 7 and the gain control section 8 so that thesections 7, 8 stop operating, and starts operation clock supply to theADC 32 and the reception start determine section 33 so that they startoperating. The power control circuit 52, in response to the packetterminate signal, stops power supply to the AGC circuit 22, the IF mixercircuits 23 a, 23 b, the LPF circuits 25 a, 25 b, and the amplifiercircuits 26 a, 26 b, all in the intermediate frequency signal processorsection 5, so that the circuits stop operating, and starts power supplyto the RSSI circuit 31 so that the circuit 31 can operate.

Next will be described steps of controlling the operation state of eachmember in the receiver section 2 in the wireless LAN terminal 1 inreference to the FIG. 2 flow chart.

First, in the wireless LAN terminal 1, in reception standby periods whenno data is being received, only the radio frequency signal processorsection 4, the signal detector section 6, and the operation statecontrol section 9 (operation clock control circuit 51 and power controlcircuit 52) are in operation; the circuits in the intermediate frequencysignal processor section 5 (analog section 10), as well as the gaincontrol section 8 and the digital demodulator section 7 (digital section20), are not in operation. The intermediate frequency oscillator 21 inthe analog section 10 may or may not operate depending on mode selection(will be detailed later).

In other words, in the reception standby period, the power controlcircuit 52 stops power supply to the AGC circuit 22, the IF mixercircuits 23 a, 23 b, the LPF circuits 25 a, 25 b, and the amplifiercircuits 26 a, 26 b, all in the intermediate frequency signal processorsection 5. Also, the operation clock control circuit 51 stops operationclock supply to the digital demodulator section 7 and the gain controlsection 8. This suspension of power supply to the circuits in theintermediate frequency signal processor section 5 in the receptionstandby period contributes to power savings. This is especially truewith the wireless LAN terminal which stands by for an extended period oftime for reception.

Note that the wireless LAN terminal 1 is able to recognize a data(packet) transmission to itself throughout the reception standby period,because the radio frequency signal processor section 4 and the signaldetector section 6 are still in operation.

The wireless LAN terminal 1 allows for selection of IFOSC (intermediatefrequency oscillator) power saving mode (reception standby period powersaving mode) in the reception standby period (see S1). In the IFOSCpower saving mode, the intermediate frequency oscillator 21 in theintermediate frequency signal processor section 5 is caused to stopoperating. Specifically, the power control circuit 52 stops power supplyto the intermediate frequency oscillator 21 according to an OSC controlsignal from the reception status monitor section 66 (upper layer) sothat the intermediate frequency oscillator 21 stops operating.

Under these circumstances, when IFOSC power saving mode is selected in areception standby period, the entire intermediate frequency signalprocessor section 5, including the intermediate frequency oscillator 21,the digital demodulator section 7, and the gain control section 8 areturned off (stop operating), with only the radio frequency signalprocessor section 4 and the signal detector section 6 being turned on(see S2). This suspension of power supply to the high power-consumingIFOSC (intermediate frequency oscillator) 21 in reception standbyperiods contributes to further power savings.

If IFOSC power saving mode is not selected in a reception standby periodor if the mode is deselected (S3), all circuits in the intermediatefrequency signal processor section 5, except for the intermediatefrequency oscillator 21, (namely, the AGC circuit 22, the IF mixercircuits 23 a, 23 b, the LPF circuits 25 a, 25 b, and the amplifiercircuits 26 a, 26 b), the digital demodulator section 7, and the gaincontrol section 8 are turned off (stop operating), with the intermediatefrequency oscillator 21, the radio frequency signal processor section 4,and the signal detector section 6 being turned on (starting operating)(see S4).

If the signal detector section 6 detects a signal coming from the radiofrequency signal processor section 4 (S5), the wireless LAN terminal 1switches from reception standby state to reception state to startreception (S6). The signal processing flow (S4 to S6) is explained indetail in the following.

A signal (radio frequency signal), received by the antenna 11, isamplified by the low noise amplifier 12 at a low NF. In the radiofrequency mixer (RF mixer) 14, the output signal from the low noiseamplifier (LNA) 12 is mixed with an oscillating signal from the radiofrequency oscillator (RFOSC) 13 for down conversion to an intermediatefrequency signal. The output signal from the radio frequency mixer 14 isfed to the bandpass filter 15 where unnecessary components are removedfrom the signal.

The output signal from the bandpass filter 15 is fed to the receptionstrength sensor section (RSSI) 31 where the RSSI value (receptionstrength) of the signal is sensed. The RSSI value, as sensed by the RSSIcircuit 31, is digitized in the A/D converter 32 and supplied to thereception start determine section 33. If the RSSI value increases inexcess of a threshold increase value (over an early part of the RSSIvalue), the reception start determine section 33 determines that it hasdetected a signal (Yes in S5) and supplies a reception start signal tothe operation state control section 9. Reception is hence started (S6).

In response to the reception start signal from the reception startdetermine section 33, in the operation state control section 9, thepower control circuit 52 starts supplying power to the circuits in theintermediate frequency signal processor section 5, and the operationclock control circuit 51 starts supplying an operation clock to thedigital demodulator section 7 and the gain control section 8.

These actions turn on (activate) the AGC circuit 22, the IF mixercircuits 23 a, 23 b, the LPF circuits 25 a, 25 b, and the amplifiercircuits 26 a, 26 b, all in the intermediate frequency signal processorsection 5, which have been off (out of operation). The actions also turnon the digital demodulator section 7 and the gain control section 8which have been off (out of operation) (see S7). The radio frequencysignal processor section 4, the intermediate frequency oscillator 21,and the signal detector section 6 which have been on (in operation)remain on (in operation) (see S7).

As the gain control section 8 is energized (turned on), the receptionstart determine section 33 passes the reception strength from the ADC 32on to the AGC control circuit 50. The AGC control circuit 50 controlsthe AGC circuit 22 through the DAC 60 on the basis of the receptionstrength. When the AGC circuit 22 completes the control (S8), the AGCcontrol circuit 50 transmits an AGC control completion signal to theoperation state control section 9.

This causes a switching to reception period power saving mode.Specifically, having received the AGC control completion signal, theoperation clock control circuit 51 stops operation clock supply to theADC 32 and the reception start determine section 33. The power controlcircuit 52 stops power supply to the RSSI circuit 31. Thus, the signaldetector section 6 stops operating, whereas the radio frequency signalprocessor section 4, the intermediate frequency signal processor section5, the digital demodulator section 7, and the gain control section 8remain in operation. This action of suspending the operation of thesignal detector section 6 (especially, suspending the power supply tothe RSSI circuit 31) during signal reception (from the start ofreception to the termination of the reception) contributes to furtherpower savings.

it is preferred if the reception period power saving mode is the defaultmode. The mode may not be selected (S9); in which case, the sameoperation state as in S7 continues with the signal detector section 6,the radio frequency signal processor section 4, the intermediatefrequency signal processor section 5, the digital demodulator section 7,and the gain control section 8 are all turned on (S1).

Following S10 or S11, packet data is demodulated (S12). The signalprocessing in S12 is now detailed in the following.

When the AGC control circuit 50 completes the control of the AGC circuit22 in S8, a signal output of the bandpass filter 15 is suitablygain-regulated in the AGC circuit 22 and fed to both the intermediatefrequency mixer circuit 23 a and the intermediate frequency mixercircuit 23 b.

One of the signal outputs from the AGC circuit 22 is mixed in theintermediate frequency mixer circuit 23 a with an oscillating signalfrom the intermediate frequency oscillator 21. Thus, the intermediatefrequency mixer circuit 23 a outputs a baseband signal (in-phasecomponent) to the LPF circuit 25 a where unnecessary components areremoved. The signal output of the LPF circuit 25 a is fed to theamplifier circuit 26 a for amplification. The signal output of theamplifier circuit 26 a is fed to the ADC 41 a in the digital demodulatorsection 7.

The other signal output from the AGC circuit 22 is mixed in theintermediate frequency mixer circuit 23 b with the oscillating signalfrom the intermediate frequency oscillator 21 after a π/2 phase-shiftingof the oscillating signal. Thus, the intermediate frequency mixercircuit 23 b outputs a baseband signal (quadrature component) to the LPFcircuit 25 b where unnecessary components are removed. The signal outputof the LPF circuit 25 b is fed to the amplifier circuit 26 b foramplification. The signal output of the amplifier circuit 26 b is fed tothe ADC 41 b in the digital demodulator section 7.

The baseband demodulator circuit (BB demodulator circuit) 42 in thedigital demodulator section 7 demodulates the incoming signal (packetdata) to the wireless LAN terminal 1 according to the signals from theA/D converter 41 a and the A/D converter 41 b. The demodulated data ispassed to an upper layer. Having completed the signal demodulation(S13), the baseband demodulator circuit 42 sends a packet demodulationterminate signal to the operation state control section 9. Thus, thewireless LAN terminal 1 switches back to reception standby state (S14).

Specifically, having received a packet demodulation terminate signalfrom the baseband demodulator circuit 42, the power control circuit 52in the operation state control section 9 stops power supply to all thecircuits in the intermediate frequency signal processor section 5 (theAGC circuit 22, the IF mixer circuits 23 a, 23 b, the LPF circuits 25 a,25 b, and the amplifier circuits 26 a, 26 b) and starts power supply tothe RSSI circuit 31 in the signal detector section 6. The operationclock control circuit 51 stops operation clock supply to the digitaldemodulator section 7 and the gain control section 8, and starts powersupply to the ADC 32 and the reception start determine section 33 in thesignal detector section 6.

The following is a further explanation of embodiments 1 and 2 above.

As detailed in the foregoing, according to the receiver device inaccordance with the present invention, the power control sectioncontrols power supply to the circuits in the second signal processorsection (intermediate frequency signal processor section) according tothe result of the sensing by the reception strength sensor section. As aresult, unlike conventional art where the entire analog section isalways powered and kept in operation, power waste in the second signalprocessor section (intermediate frequency signal processor section) isgreatly reduced while the analog section is waiting for a signal to bereceived (during reception standby). The arrangement thus achieves powersavings in the receiver device.

As described so far, it is preferred if: the second signal processorsection includes a gain regulator circuit gain-regulating a signal fromthe first signal processor section and an amplifier circuit amplifying asignal from the gain regulator circuit; and the power control sectionsuspends power supply to the gain regulator circuit and the amplifiercircuit while the result of the sensing does not meet a predeterminedcondition, and starts power supply to the gain regulator circuit and theamplifier circuit when the result of the sensing comes to meet thepredetermined condition.

According to the arrangement, the signal from the first signal processorsection undergoes gain regulation (for example, auto gain control) andamplification processes in the gain regulator circuit and the amplifiercircuit in the second signal processor section. The power controlsection controls power supply to the gain regulator circuit and theamplifier circuit according to a result of the sensing by the receptionstrength sensor section. Specifically, the power control sectionsuspends power supply to the gain regulator circuit and the amplifiercircuit until the result of the sensing by the reception strength sensorsection meets a predetermined condition. As a result, power waste in thegain regulator circuit and the amplifier circuit is greatly reducedwhile waiting for a signal to be received (demodulatable signal) (duringreception standby).

It is also preferred if the receiver device of the present is adapted sothat: the power control section is capable of controlling power supplyto the reception strength sensor section; and the power control sectionsuspends power supply to the reception strength sensor section when thegain regulator circuit is powered on and completes gain regulation.

The arrangement allows for suspension of power supply to the receptionstrength sensor section when the result of the sensing by the receptionstrength sensor section meets a predetermined condition, and the gainregulator circuit operates and completes gain regulation. Thearrangement is applicable, because after completion of gain regulation,the reception strength sensor section does not need to be in operationuntil the demodulator section completes signal demodulation. This actionof suspending power supply to the reception strength sensor section whenthe reception strength sensor section does not need to be in operationallows for more power savings.

The receiver device may be arranged to further include: a gain controlsection controlling the gain regulator circuit; and a digital operationcontrol section controlling operation states of the gain control sectionand the demodulator section.

It is preferred if the receiver device is adapted so that in a receptionstandby period when the result of the sensing does not meet thepredetermined condition, the power control section supplies power to thefirst signal processor section and the reception strength sensorsection, but does not supply power to the second signal processorsection, and the digital operation control section causes thedemodulator section and the gain control section to stop operating.

In the reception standby period, the arrangement allows for suspensionof power supply to the second signal processor section, which does notneed to be in operation, and suspension of the operation of thedemodulator section and the gain control section. The arrangement thuscontributes to further power savings.

In the receiver device, when the result of the sensing comes to meet thepredetermined condition, the power control section starts power supplyto the second signal processor section and continues to supply power tothe first signal processor section and the reception strength sensorsection, and the digital operation control section causes thedemodulator section and the gain control section to start operating. Thearrangement subjects the signal from the first signal processor sectionto gain regulation and amplification processes in the second signalprocessor section and the signal from the second signal processorsection to demodulation in the demodulator section to reproducetransmitted information.

It is also preferred if the receiver device is adapted so that: thereceiver device allows for selection of reception period power savingmode in which when the gain control section ends control of the gainregulator circuit; and the power control section suspends power supplyto the reception strength sensor section, but continues to supply powerto the second signal processor section, and the digital operationcontrol section causes the demodulator section and the gain controlsection to remain in operation.

According to the arrangement, when the result of the sensing meets thepredetermined condition, the gain control section controls the gainregulator circuit in the second signal processor section. Thus, thesignal from the first signal processor section is optimallygain-regulated by the gain regulator circuit, before going through theamplifier circuit in the second signal processor section and beingpassed onto the demodulator section. This action of suspending powersupply to the reception strength sensor section which does not need tobe in operation while the power control section is in a receivingprocess following the end of the control of the gain regulator circuitcontributes to further power savings.

It is also preferred if: the intermediate frequency signal processorsection includes an IF oscillator and a IF mixer circuit mixing a signalfrom the IF oscillator with a signal from the radio frequency signalprocessor section; and the power control section suspends power supplyto the IF mixer circuit while the result of the sensing does not meet apredetermined condition, and starts power supply to the IF mixer circuitwhen the result of the sensing comes to meet the predeterminedcondition.

According to the arrangement, the signal from the radio frequency signalprocessor section is mixed with the signal from the IF oscillator in theIF mixer circuit in the intermediate frequency signal processor section,and converted to a lower frequency (for example, baseband signal). Thepower control section controls power supply to the IF mixer circuitaccording to the result of the sensing by the reception strength sensorsection. Specifically, the power control section suspends power supplyto the IF mixer circuit until the result of the sensing by the receptionstrength sensor section meets the predetermined condition. As a result,power waste in the IF mixer circuit is eradicated while waiting for asignal to be received (demodulatable signal) (during reception standby).

It is preferred if: the intermediate frequency signal processor sectionfurther includes: a gain regulator circuit gain-regulating the signalfrom the radio frequency signal processor section for output to the IFmixer circuit; a low pass filter circuit where a signal from the IFmixer circuit is input; and an amplifier circuit amplifying a signalfrom the low pass filter circuit; and the power control section suspendspower supply to the gain regulator circuit, the low pass filter circuit,and the amplifier circuit while the result of the sensing does not meetthe predetermined condition, and starts power supply to the gainregulator circuit, the low pass filter circuit, and the amplifiercircuit when the result of the sensing comes to meet the predeterminedcondition.

According to the arrangement, the signal from the radio frequency signalprocessor section is gain-regulated by the gain regulator circuit, mixedwith the signal from the IF oscillator in the IF mixer circuit, andconverted to a lower frequency (for example, baseband signal). Theoutput signal from the IF mixer circuit is fed to the low pass filtercircuit where unnecessary components are removed, and amplified by theamplifier circuit. The power control section controls power supply tothe gain regulator circuit, the low pass filter circuit, and theamplifier circuit according to the result of the sensing by thereception strength sensor section. Specifically, the power controlsection suspends power supply to the gain regulator circuit, the lowpass filter circuit, and the amplifier circuit until the result of thesensing by the reception strength sensor section meets the predeterminedcondition. As a result, power waste in the gain regulator circuit, thelow pass filter circuit, and the amplifier circuit is eradicated whilewaiting for a signal to be received (demodulatable signal) (duringreception standby).

It is also preferred if the receiver device in accordance with thepresent invention is adapted so that the IF oscillator is powered onregardless of the result of the sensing. The arrangement eliminates theneed for an element controlling power supply to the IF oscillator (forexample, from the upper layer), allowing for simplified structure.

The receiver device in accordance with the present invention may beadapted so that: the power control section is capable of controllingpower supply to the IF oscillator; and the power control sectioncontrols the power supply to the IF oscillator according to a result ofmonitoring by a reception status monitor section monitoring receptionstatus of the radio frequency signal processor section.

According to the arrangement, controlling power supply to the IFoscillator, which is a high power consuming component in theintermediate frequency signal processor section, allows for more powersavings.

It is also preferred if the receiver device in accordance with thepresent invention is adapted so that: the power control section iscapable of controlling power supply to the reception strength sensorsection; and the power control section suspends power supply to thereception strength sensor section when the gain regulator circuit ispowered on and completes gain regulation.

The arrangement allows for suspension of power supply to the receptionstrength sensor section when the result of the sensing by the receptionstrength sensor section meets a predetermined condition, and the gainregulator circuit operates and completes gain regulation. Thearrangement is applicable, because after completion of gain regulation,the reception strength sensor section does not need to be in operationuntil the demodulator section completes signal demodulation. This actionof suspending power supply to the reception strength sensor section whenthe reception strength sensor section does not need to be in operationallows for more power savings.

The receiver device may be arranged so that the power control section isfurther capable of controlling power supply to the IF oscillator, andincludes a gain control section controlling the gain regulator circuitand a digital operation control section controlling operation states ofthe gain control section and the demodulator section.

It is also preferred if the receiver device is adapted so that in areception standby period when the result of the sensing does not meetthe predetermined condition, the power control section supplies power tothe radio frequency signal processor section and the reception strengthsensor section, but does not supply power to circuits in theintermediate frequency signal processor section, and the digitaloperation control section causes the demodulator section and the gaincontrol section to stop operating.

In the reception standby period, the arrangement allows for suspensionof power supply to the circuits in the intermediate frequency signalprocessor section, which do not need to be in operation, and suspensionof the operation of the demodulator section and the gain controlsection. The arrangement thus contributes to further power savings.

It is also preferred if the receiver device is adapted so that: thereceiver device allows for selection of reception standby period powersaving mode; and the power control section suspends power supply to theIF oscillator in the reception standby period power saving mode, andstarts power supply to the oscillator when the reception standby periodpower saving mode ends. According to the arrangement, in the receptionstandby period, power supply to the IF oscillator, which does not needto be in operation, is suspended. This contributes to further powersavings.

In the receiver device, when the result of the sensing comes to meet thepredetermined condition, the power control section starts power supplyto circuits in the intermediate frequency signal processor section andcontinues to supply power to the IF oscillator, the radio frequencysignal processor section, and the reception strength sensor section, andthe digital operation control section causes the demodulator section andthe gain control section to start operating. The arrangement subjectsthe signal from the radio signal processor section to gain regulation,down conversion, unnecessary components removal, and amplificationprocesses in the intermediate frequency signal processor section. Thesignal from the intermediate frequency signal processor section isdemodulated in the demodulator section to reproduce transmittedinformation.

It is also preferred if the receiver device is adapted so that thereceiver device allows for selection of reception period power savingmode in which when the gain control section ends control of the gainregulator circuit, the power control section suspends power supply tothe reception strength sensor section and continues to supply power tothe IF oscillator and the circuits in the intermediate frequency signalprocessor section, and the digital operation control section causes thedemodulator section and the gain control section to continue to operate.

According to the arrangement, when the result of the sensing meets thepredetermined condition, the gain control section controls the gainregulator circuit in the intermediate frequency signal processorsection. Thus, the signal from the radio frequency signal processorsection is optimally gain-regulated by the gain regulator circuit,before being mixed with the signal from the IF oscillator (downconversion), going through the low pass filter circuit and the amplifiercircuit in the intermediate frequency signal processor section, andbeing passed onto the demodulator section. This action of suspendingpower supply to the reception strength sensor section which does notneed to be in operation while the power control section is in areceiving process following the end of the control of the gain regulatorcircuit contributes to further power savings.

A communications device in accordance with the present invention ischaracterized by the inclusion of the receiver device.

A wireless LAN device in accordance with the present invention ischaracterized in that the inclusion of the receiver device.

A power control method for a receiver device in accordance with thepresent invention, to address the issues, is applied to a receiverdevice including: a first signal processor section converting anincoming radio frequency signal to a lower frequency; a receptionstrength sensor section sensing a signal strength of the radio frequencysignal; and a second signal processor section carrying out a process ona signal from the first signal processor section to improve demodulationprecision, and is characterized in that the method includes: suspendingpower supply to circuits in the second signal processor section while aresult of the sensing by the reception strength sensor section does notmeet a predetermined condition; and starting power supply to thecircuits in the second signal processor section when the result of thesensing comes to meet the predetermined condition.

Another power control method for a receiver device in accordance withthe present invention, to address the issues, is applied to a receiverdevice including: a radio frequency signal processor section convertingan incoming radio frequency signal to a lower frequency; a receptionstrength sensor section sensing a signal strength of the radio frequencysignal; and an intermediate frequency signal processor sectionconverting a signal from the radio frequency signal processor section toan even lower frequency, and is characterized in that the methodincludes: suspending power supply to circuits in the intermediatefrequency signal processor section while a result of the sensing by thereception strength sensor section does not meet a predeterminedcondition; starting power supply to the circuits in the intermediatefrequency signal processor section when the result of the sensing comesto meet the predetermined condition.

A power control program for a receiver device in accordance with thepresent invention is characterized in that the program causes a computerto implement the power control method for a receiver device.

A computer-readable storage medium in accordance with the presentinvention is characterized in that the medium contains the power controlprogram for a receiver device.

Embodiments 1, 2 assumed that the operation of each component in thedigital section is controlled through the suspension/start of anoperation clock supply from the operation clock control circuit. This ishowever not the only possibility. For example, the power control circuitmay control power supply to the components (ADC, reception startdetermine section, digital demodulator section, gain control section) inthe digital section. The functionality of the operation state controlsection may be implemented either in hardware or by a computer executinga program. An example of the latter case is a CPU or similar computingmeans executing program code contained in a ROM, RAM, or other storagemedium.

In addition, embodiments 1, 2 assumed a double heterodyne or directconversion system. The receiver device in accordance with the presentinvention may however be applied to other kinds of systems as well. Thearrangements of the present invention are applicable to any receiver inwhich an analog processor section (second analog processor section: forexample, second signal processor section or intermediate frequencysignal processor section) is provided between the radio frequency signal(RF) processor section (first analog processor section: for example,first signal processor section) and the digital processor section (forexample, demodulator section) for the purpose of improving demodulationprecision. With the invention being applied, the power control sectioncan control power supply to the second analog processor section.

The receiver device in accordance with the present invention may bedefined as including: a first signal processor section converting anincoming radio frequency signal to a lower frequency; a receptionstrength sensor section sensing a signal strength of the radio frequencysignal; a second signal processor section carrying out a process on asignal from the first signal processor section to improve demodulationprecision; a demodulator section demodulating a signal from the secondsignal processor section; and an operation state control sectioncontrolling start/suspension of the operation of circuits in the secondsignal processor section according to a result of the sensing by thereception strength sensor section.

The receiver device in accordance with the present invention may bedefined as including: a radio frequency signal processor sectionconverting an incoming radio frequency signal to a lower frequency; areception strength sensor section sensing a signal strength of the radiofrequency signal; an intermediate frequency signal processor sectionconverting a signal from the radio frequency signal processor section toan even lower frequency; a demodulator section demodulating a signalfrom the intermediate frequency signal processor section; and anoperation state control section controlling start/suspension of theoperation of circuits in the intermediate frequency signal processorsection according to a result of the sensing by the reception strengthsensor section.

The receiver device in accordance with the present invention areapplicable to, for example, a wireless LAN terminal mounted in PDAs andother mobile terminals.

The invention being thus described, it will be obvious that the same waymay be varied in many ways. Such variations are not to be regarded as adeparture from the spirit and scope of the invention, and all suchmodifications as would be obvious to one skilled in the art are intendedto be included within the scope of the following claims.

1. A receiver device, comprising: a first signal processor sectionconverting an incoming radio frequency signal to a lower frequency; areception strength sensor section sensing a signal strength of the radiofrequency signal; a second signal processor section carrying out aprocess on a signal from the first signal processor section to improvedemodulation precision; a demodulator section demodulating a signal fromthe second signal processor section; and a power control sectioncontrolling power supply to circuits in the second signal processorsection according to a result of sensing by the reception strengthsensor section, wherein: the second signal processor section includes: again regulator circuit gain-regulating the signal from the first signalprocessor section; and an amplifier circuit amplifying a signal from thegain regulator circuit; and the power control section suspends powersupply to the gain regulator circuit and the amplifier circuit while theresult of the sensing does not meet a predetermined condition, andstarts power supply to the gain regulator circuit and the amplifiercircuit when the result of the sensing comes to meet the predeterminedcondition.
 2. The receiver device as set forth in claim 1, wherein: thepower control section is capable of controlling power supply to thereception strength sensor section; and the power control sectionsuspends power supply to the reception strength sensor section when thegain regulator circuit is powered on and completes gain regulation. 3.The receiver device as set forth in claim 1, further comprising: a gaincontrol section controlling the gain regulator circuit; and a digitaloperation control section controlling operation states of the gaincontrol section and the demodulator section.
 4. The receiver device asset forth in claim 3, wherein in a reception standby period when theresult of the sensing does not meet the predetermined condition, thepower control section supplies power to the first signal processorsection and the reception strength sensor section, but does not supplypower to the second signal processor section, and the digital operationcontrol section causes the demodulator section and the gain controlsection to stop operating.
 5. The receiver device as set forth in claim3, wherein when the result of the sensing comes to meet thepredetermined condition, the power control section starts power supplyto the second signal processor section and continues to supply power tothe first signal processor section and the reception strength sensorsection, and the digital operation control section causes thedemodulator section and the gain control section to start operating. 6.The receiver device as set forth in claim 5, wherein the receiver deviceallows for selection of reception period power saving mode in which whenthe gain control section ends control of the gain regulator circuit, thepower control section suspends power supply to the reception strengthsensor section, but continues to supply power to the second signalprocessor section, and the digital operation control section causes thedemodulator section and the gain control section to remain in operation.7. A communications device, comprising the receiver device as set forthin claim
 1. 8. A wireless Local Area Network (LAN) device, comprisingthe receiver device as set forth in claim
 1. 9. A receiver device,comprising: a radio frequency signal processor section converting anincoming radio frequency signal to a lower frequency; a receptionstrength sensor section sensing a signal strength of the radio frequencysignal; an intermediate frequency signal processor section converting asignal from the radio frequency signal processor section to an evenlower frequency; a demodulator section demodulating a signal from theintermediate frequency signal processor section; and a power controlsection controlling power supply to circuits in the intermediatefrequency signal processor section according to a result of sensing bythe reception strength sensor section, wherein: the intermediatefrequency signal processor section includes an Intermediate Frequency(IF) oscillator and a if mixer circuit mixing a signal from the IFoscillator with a signal from the radio frequency signal processorsection; and the power control section suspends power supply to the IFmixer circuit while the result of the sensing does not meet apredetermined condition, and starts power supply to the If mixer circuitwhen the result of the sensing comes to meet the predeterminedcondition.
 10. The receiver device as set forth in claim 9, wherein: theintermediate frequency signal processor section further includes: a gainregulator circuit gain-regulating the signal from the radio frequencysignal processor section for output to the IF mixer circuit; a low passfilter circuit where a signal from the IF mixer circuit is input; and anamplifier circuit amplifying a signal from the low pass filter circuit;and the power control section suspends power supply to the gainregulator circuit, the low pass filter circuit, and the amplifiercircuit while the result of the sensing does not meet the predeterminedcondition, and starts power supply to the gain regulator circuit, thelow pass filter circuit, and the amplifier circuit when the result ofthe sensing comes to meet the predetermined condition.
 11. The receiverdevice as set forth in claim 10, wherein the power control section iscapable of controlling power supply to the reception strength sensorsection; and the power control section suspends power supply to thereception strength sensor section when the gain regulator circuit ispowered on and completes gain regulation.
 12. The receiver device as setforth in claim 10, wherein the power control section is further capableof controlling power supply to the IF oscillator, and includes a gaincontrol section controlling the gain regulator circuit and a digitaloperation control section controlling operation states of the gaincontrol section and the demodulator section.
 13. The receiver device asset forth in claim 12, wherein in a reception standby period when theresult of the sensing does not meet the predetermined condition, thepower control section supplies power to the radio frequency signalprocessor section and the reception strength sensor section, but doesnot supply power to circuits in the intermediate frequency signalprocessor section, and the digital operation control section causes thedemodulator section and the gain control section to stop operating. 14.The receiver device as set forth in claim 13, wherein: the receiverdevice allows for selection of reception standby period power savingmode; and the power control section suspends power supply to the IFoscillator in the reception standby period power saving mode, and startspower supply to the IF oscillator when the reception standby periodpower saving mode ends.
 15. The receiver device as set forth in claim12, wherein when the result of the sensing comes to meet thepredetermined condition, the power control section starts power supplyto circuits in the intermediate frequency signal processor section andcontinues to supply power to the IF oscillator, the radio frequencysignal processor section, and the reception strength sensor section, andthe digital operation control section causes the demodulator section andthe gain control section to start operating.
 16. The receiver device asset forth in claim 15, wherein the receiver device allows for selectionof reception period power saving mode in which when the gain controlsection ends control of the gain regulator circuit, the power controlsection suspends power supply to the reception strength sensor section,but continues to supply power to the IF oscillator and the circuits inthe intermediate frequency signal processor section, and the digitaloperation control section causes the demodulator section and the gaincontrol section to continue to operate.
 17. The receiver device as setforth in claim 9, wherein the IF oscillator is powered on regardless ofthe result of the sensing.
 18. The receiver device as set forth in claim9, wherein: the power control section is capable of controlling powersupply to the IF oscillator; and the power control section controls thepower supply to the IF oscillator according to a result of monitoring bya reception status monitor section monitoring reception status of theradio frequency signal processor section.
 19. A communications device,comprising said receiver device as set forth in claim
 9. 20. A wirelessLocal Area Network (LAN) device, comprising said receiver device as setforth in claim
 9. 21. A power control method for a receiver deviceincluding: a first signal processor section converting an incoming radiofrequency signal to a lower frequency; a reception strength sensorsection sensing a signal strength of the radio frequency signal; and asecond signal processor section carrying out a process on a signal fromthe first signal processor section to improve demodulation precision,the second signal processor section including a gain regulator circuitgain-regulating the signal from the first signal processor section andan amplifier circuit amplifying a signal from the gain regulatorcircuit, said method comprising: suspending power supply the gainregulator circuit and the amplifier circuit in the second signalprocessor section while a result of the sensing by the receptionstrength sensor section does not meet a predetermined condition; andstarting power supply to the gain regulator circuit and the amplifiercircuit in the second signal processor section when the result of thesensing comes to meet the predetermined condition.
 22. A power controlmethod for a receiver device including: a radio frequency signalprocessor section converting an incoming radio frequency signal to alower frequency; a reception strength sensor section sensing a signalstrength of the radio frequency signal; and an intermediate frequencysignal processor section converting a signal from the radio frequencysignal processor section to an even lower frequency, the intermediatefrequency signal processor section including an Intermediate Frequency(IF) oscillator and a IF mixer circuit mixing a signal from the IFoscillator with a signal from the radio frequency signal processorsection, said method comprising: suspending power supply to the IF mixercircuit in the intermediate frequency signal processor section while aresult of the sensing by the reception strength sensor section does notmeet a predetermined condition; and starting power supply to the IFmixer circuit in the intermediate frequency signal processor sectionwhen the result of the sensing comes to meet the predeterminedcondition.